Abstract
The authors consider the issue of energy saving in pneumatic drives of the technological equipment. The principal circuit of the energy saving pneumatic drive is provided. The energy consumption decreases at the retardation of the output element of the pneumatic drive with the help of reverse pressure, blocking the pneumatic cylinder chambers and the recuperation of the energy of the air, compressed in the output chamber, in an additional volume, with its subsequent use for the pneumatic drive output element reverse motion. The authors present a mathematical model of dynamic processes, describing the acceleration and retardation of the pneumatic drive output element. Changing the initial parameters of the additional volume provides an opportunity for the efficient control of energy and speed-drive characteristics. The authors compared the known pneumatic drive retardation methods with the suggested retardation method by means of the energy recuperation with pre-set initial parameters.
This is a preview of subscription content, log in via an institution.
Buying options
Tax calculation will be finalised at checkout
Purchases are for personal use only
Learn about institutional subscriptionsReferences
Yusop MYM (2006) Energy saving for pneumatic actuation using dynamic model prediction. Dissertation, school of engineering, Cardiff University, 212p
Blagojevic Vladislav, Šešlija Dragan, Stojiljkovic Miodrag (2011) Cost effectiveness of restoring energy in execution part of pneumatic system. J Sci Ind Res 70:170–176
Diachenko AD, Udovkin AI, Sirotenko AN (2006) Improving characteristics of pneumatic drive of unit for liquid product pre-packing and packing. Improving processes and technical means in agroindustrial complex: 4. Collection of scientific papers. Ministry of Agriculture and Food of the Russian Federation. Azov and Black Sea Region Academy of Agricultural Mechanization, Zernograd, p 79–81
Sirotenko AN, Partko SA (2015) Improvement of characteristics of a pneumodrive of table turn of packaging and filling machine. In: 8th international scientific-practical conference materials: condition and prospects of development of agricultural machine-building, Within the framework of the 18th International agricultural industry. Sp. “Interagromash 2015”, Rostov-on-Don, p 179–182
Diachenko AG, SavostinaTP, Kolpakov MV (2018) Development of structure of feeding machine for cylindrical parts. In: Innovative materials and technologies: collection of articles on outcomes of international research-to-practice conference, Sterlitamak, p 11–13
Filipov IB (1987) Deceleration devices of pneumatic actuator. Machine-building, Leningrad
Krytikov G, Strizhak M, Strizhak V (2017) The synthesis of structure and parameters of energy efficient pneumatic actuator. Eastern-Eur J Enterp Technol 1(7):38–44
Sirotenko AN, Partko SA (2014) Energy-saving pneumatic actuator of technological equipment. Materials of VI Intern. scientific-practical. In: Conferrence: innovative technologies in machine-building and metallurgy, Rostov-on-Don, p 173–178
Hertz EV (1985) Dynamics of pneumatic systems of machines. Machine-building, Moskow
Anh Dao The, Sidorenko VS, Dymochkin DD (2014) Dynamics of position fast robot with pneumatic drive of brake unit. Dyn Vibroacoustics Mach Conf 3:176–183
Sirotenko AN, Chernavsky VA (1998) Mathematical model of valve hydraulic absorber. Hydraulic pneumatic systems of technological and mobile machines: inter-university collection of scientific papers, Rostov-on-Don, p 28–32
Dao TA, Sidorenko VS, Dymochkin DD (2015) Study on positioning accuracy of automated pneumatic drive with an outer brake. Vestnik Don State Tech Univ 15(4):46–53
Grishchenko VI, Sidorenko VS, Poleshkin MS (2009) Pneumatic position drive. Patent RUS for invention 2450174
Grishchenko VI, Kilina MS, Chernavskiy VA (2012) Positioning dynamics of drive gears with hydroabsorber. Vestnik Don State Tech Univ 12(4):16–21
Poleshkin MS, Al-Kudakh AM, Grishchenko VI, Sidorenko VS (2008) Identification of operation processes in multifunctional braking device. In: Hydraulic machines, hydraulic drives and hydraulic pneumatic automation: proceedings of reports of the 12th international science and technology conference, Moscow, p 54–55
Grishchenko VI, Al-Kudakh AM, Poleshkin MS, Sidorenko VS (2008) Structural and parametric control of position pneumatic hydraulic mechanical device. In: Hydraulic machines, hydraulic drives and hydraulic pneumatic automation: proceedings of reports of the 12th international science and technology conference of students and post-graduate students. Ministry of Education and Science of the Russian Federation, Moscow Power Engineering Institute (Technical University), Bauman Moscow State Technical University, Moscow, p 22–23
Sirotenko AN, Partko SA (2017) Decrease in power inputs in pneumodrive weighing-and-packing machine. Int J Appl Eng Res 12(14):4599–4603
Sirotenko AN, Partko SA (2017) Mathematical model of dynamic processes of pneumatic drive during braking by reverse pressure, with recovery of energy into additional volume. Sci Rev 1:67–74
Sirotenko AN, Partko SA (2018) Calculation of dynamic parameters of pneumatic hydraulic drive with energy recovery. Certificate of registration of the computer program, RUS 2018613130 RF
Sirotenko AN, Partko SA (2018) Calculation of dynamic characteristics of pneumatic-mechanical drive. Certificate of registration of the computer program, RUS 2018663925 RF
Udovkin AI, Sirotenko AN (2009) Experimental check of validity of mathematical model of cost-efficient pneumatic drive of the unit “Alur-1500”, Improving processes and technical means in agroindustrial complex: collection of scientific Papers– Zernograd/ FGOU VPO ACHGAA 8:50–52
Sirotenko AN, Partko SA, Saed BA (2017) Dependence of energy-speed characteristics of pneumatic drive on initial parameters of additional volume under counterpressure braking. Vestnik Don State Tech Univ 17(4):69–76
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2020 Springer Nature Switzerland AG
About this paper
Cite this paper
Sirotenko, A.N., Partko, S.A., Voinash, S.A. (2020). Research of Pneumodrive with Energy Recovery into Additional Volume. In: Radionov, A., Kravchenko, O., Guzeev, V., Rozhdestvenskiy, Y. (eds) Proceedings of the 5th International Conference on Industrial Engineering (ICIE 2019). ICIE 2019. Lecture Notes in Mechanical Engineering. Springer, Cham. https://doi.org/10.1007/978-3-030-22063-1_140
Download citation
DOI: https://doi.org/10.1007/978-3-030-22063-1_140
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-22062-4
Online ISBN: 978-3-030-22063-1
eBook Packages: EngineeringEngineering (R0)